FR3118083A1 - Electric door unlocking system - Google Patents

Abstract

Electric door unlocking system This electric door unlocking system comprises: - an electric actuator (10; 150) capable of switching between: - a locked state in which it keeps the door locked, and - an unlocked state in which it keeps the door unlocked, - a circuit (66) for detecting the state of a switch connected between first and second fixed pads (34, 36) of this switch, this detection circuit being able: - to comparing the voltage or the intensity of the current between the first and second fixed pads of the switch, with a predetermined threshold, and - in response to the crossing of this predetermined threshold, in generating and transmitting a depression signal to a circuit control (64) of a timed relay which maintains the actuator in its unlocked state. Fig. 1

Description

Electric door unlocking system

The invention relates to an electric unlocking system for a door. It also relates to an electronic card for the realization of this system.

Electric door unlocking systems must allow a normal operating mode and a degraded operating mode.

In the normal operating mode, when a user presses the button of a push button, this unlocks the door and keeps the door unlocked for a predetermined time T even if, in the meantime, the user has released the push button .

Keeping the door unlocked for the duration T is controlled by an electronic card comprising an electrical circuit for controlling a timed relay. This driver circuit controls the switching of the time delay relay in response to receiving a push button key depression signal. The push signal is a signal generated by the push button.

In degraded operating mode, the door must be able to be unlocked, even if the electronic card no longer works. In other words, in the event of a malfunction of the electronic card, the user must not find himself trapped inside the building without being able to get out.

To do this, the push button includes a normally closed mechanical power switch, connected in series between a power supply terminal of the electric actuator which unlocks the door and a power source for this actuator. When the pushbutton key is pressed, it moves the mechanical switch which then cuts power to the actuator. This unlocks the door without having to use the electronic card.

The mechanical power switch comprises:
- a first and a second fixed electrical pads connected, respectively, to the power supply terminal of the actuator and to a terminal of the power source, and
- A movable electrical contact moved by the button of the pushbutton between a closed state where it supplies the actuator and an open state where it cuts off the power supply to the actuator.

Moreover, in the known systems, the power switch comprises a third and a fourth electrical fixed pads isolated from the first and second fixed pads. These third and fourth fixed pads are electrically connected to each other by the electrical contact only when the power switch is in its open state. These third and fourth fixed pads are used to generate the depression signal transmitted to the electronic card. For this, the third and fourth fixed pads are connected to the electronic card by respective electric wires.

It is desirable to simplify the electrical connection between the push button and the electronic card.

It is also desirable to simplify the architecture of the push button in order, for example, to be able to integrate additional functionalities into it while maintaining an equal or smaller size.

The object of the invention is to propose a solution to at least one of these wishes. It therefore relates to an electrical unlocking system for a door comprising:
- an electric actuator capable of switching between:
- a locked state in which it keeps the door locked, and
- an unlocked state in which it keeps the door unlocked,
this actuator comprising a first and a second power supply terminals intended to be connected to a power source in order to receive the power supply necessary for its operation, and this actuator switching between its locked and unlocked states by connecting and, alternately, by disconnecting its first supply terminal from this supply source,
- a push button comprising:
- a pulse switch capable of switching between:
- a stable state in which it maintains the actuator in its locked state, and
- an unstable state in which it maintains the actuator in its unlocked state,
this switch comprising for this:
- first and second fixed electric pads, the first pad being connected to the first power supply terminal of the electric actuator by means of a first wire and the second pad being connected to the power source by the intermediary of a second thread,
- a reversibly movable electrical contact between:
- a closed state in which it electrically connects the first and second pads together, and
- an open state in which the first and second pads are electrically isolated from each other,
- a key that can be moved by a user to move the switch from its stable state to its unstable state,
- an electronic card external to the push button, this electronic card comprising:
- a timed relay switchable between:
- a state of rest in which it authorizes the switching of the actuator to its unlocked state in response to the displacement of the key of the push button, and
- an active state in which it maintains the electric actuator in its unlocked state even if the switch is in its stable state,
- a timing relay control circuit capable, in response to receiving a depression signal, of switching the timing relay from its idle state to its active state and then of maintaining the timing relay in its active state for a predetermined duration before automatically returning to its idle state,
characterized in that the system comprises a circuit for detecting the state of the switch connected between the first and second fixed pads, this detection circuit being able:
- comparing the voltage or the intensity of the current between the first and second fixed pads of the switch, with a predetermined threshold, and
- In response to the crossing of this predetermined threshold, to generate and transmit the depression signal to the control circuit.

Embodiments of this system may include one or more of the following features:
1) The detection circuit is integrated in the external electronic board.
2) only the first and second fixed pads of the switch are electrically connected to the electronic card.
3) the rest state of the time delay relay is a stable state, that is to say that in the event of a power failure of the electronic card, the time delay relay automatically returns to this rest state.
4)
- the push button comprises a proximity detector capable of detecting, without contact, the presence of a hand in front of the button of the push button, and of transmitting a detection signal to the control circuit,
- the control circuit is also able, in response to receiving the detection signal, to switch the timed relay from its idle state to its active state and then to maintain the timed relay in its active state for a predetermined duration before automatically return to its idle state.
5)
- the locked state of the electric actuator is a state in which the electric actuator is powered and the unlocked state of the electric actuator is a state in which the electric actuator is not powered,
- the push button switch is a normally closed switch such that its stable state corresponds to a state where the electrical contact is in its closed state and its unstable state corresponds to a state where the electrical contact is in its open state,
- the idle state of the time delay relay corresponds to a closed state of this time delay relay and the active state of the time delay relay corresponds to an open state of this time delay relay.
6)
- the locked state of the electric actuator is a state in which the electric actuator is not powered and the unlocked state of the electric actuator is a state in which the electric actuator is powered,
- the push button switch is a normally open switch such that its stable state corresponds to a state where the electrical contact is in its open state and its unstable state corresponds to a state where the electrical contact is in its closed state,
- the idle state of the time relay corresponds to an open state of this time relay and the active state of the time relay corresponds to a closed state of this time relay. 7)

The invention also relates to an electronic card for the realization of the above system in which this electronic card comprises:
- a timed relay switchable between:
- a state of rest in which it authorizes the switching of the actuator to its unlocked state in response to the displacement of the key of the push button, and
- an active state in which it maintains the electric actuator in its unlocked state even if the switch is in its stable state,
- a timing relay control circuit capable, in response to receiving a depression signal, of switching the timing relay from its idle state to its active state and then of maintaining the timing relay in its active state for a predetermined duration before automatically returning to its idle state,
in which the electronic card comprises a circuit for detecting the state of the switch connected between the first and second fixed pads, this detection circuit being able:
- comparing the voltage or the intensity of the current between the first and second fixed pads of the switch, with a predetermined threshold, and
- In response to the crossing of this predetermined threshold, to generate and transmit the depression signal to the control circuit.

The invention will be better understood on reading the following description, given solely by way of non-limiting example and made with reference to the drawings in which:
- there is a schematic illustration of the architecture of an electric door unlocking system;
- there is a schematic illustration of a housing of a push button for the system of the ;
- there is an exploded view of part of the elements of a push button for the system of the ;
- there is a perspective view of some of the push button elements of the ;
- Figures 5 and 6 are schematic illustrations, in perspective, of an assembly of the push button of the and a control box for the realization of the system of the ;
- there is another possible embodiment of an electric door unlocking system.

In the rest of this description, the characteristics and functions well known to those skilled in the art are not described in detail.

In this description, detailed examples of embodiments are first described in a chapter I with reference to the figures. Then, in a chapter II, variants of these embodiments are presented. Finally, the advantages of the different embodiments are presented in a chapter III.

There represents a system 2 for electrical unlocking of a door 4. The door 4 is typically the access door to a building such as an apartment building. Door 4 has a leaf 6 and a frame 8.

System 2 includes:
- an electric actuator 10 for locking and, alternately, unlocking the door 4,
- an impulse push button 12 operable by a user to unlock the door 4,
- an electronic card 14 external to the push-button 12, in particular to keep the door 4 unlocked for a predetermined duration T after the button 12 has been pressed,
- a power source 16 for the actuator 10, the button 12 and the electronic card 14.

System 2 is typically housed inside the building and therefore allows door 4 to be unlocked to exit this building.

The actuator 10 can be toggled between a locked state and an unlocked state. In the locked state, it keeps door 4 locked in its closed position. In this embodiment, this locked state corresponds to a state in which the actuator 10 is powered. In the unlocked state, door 4 is unlocked. The door 4 can then freely be moved from its closed position to its open position. This unlocked state is obtained when the power supply to actuator 10 is cut off.

Actuator 10 has two supply terminals, 20 and 22. Terminal 20 is intended to be connected to a positive terminal 162 of power source 16. Terminal 22 is connected to a terminal 164, corresponding to the ground of power source 16. Terminals 20 and 22 allow power the actuator 10 when they are connected to the power source 16. In this text, the term "terminal" designates an electrical connection terminal movable between a free position and a clamped position. In the free position, the stripped end of an electrical wire can be introduced inside the terminal. In the pinched position, the terminal retains the stripped end of the wire stuck inside this terminal.

Here, actuator 10 is an electromagnetic lock. It therefore comprises a plate 24 of ferromagnetic material and an electromagnet 26. The plate 24 is fixed without any degree of freedom on the leaf 6. The electromagnet 26 is fixed without any degree of freedom on the fixed frame 8 opposite of the plate 24. The terminals 22 and 24 supply the electromagnet 26. When the electromagnet 26 is energized, it generates a magnetic field which attracts the plate 24 and therefore maintains the door 4 in its closed and locked position.

Button 12 makes it possible to disconnect terminal 20 from power source 16. This button 12 therefore makes it possible to cut off the power supply to actuator 10 and, consequently, to switch it to its unlocked state. To this end, the button 12 comprises a power switch 30 and a button 32 for actuation.

The switch 30 is qualified as "power" because it makes it possible to cut off the power supply to the actuator 10. For this purpose, it is generally capable of cutting off a direct current greater than 0.5 A or 1 A under a voltage greater than at 24 VdC or 48 Vdc when the actuator 10 is powered by a DC voltage. When actuator 10 is supplied with alternating voltage, switch 30 is capable of breaking a current greater than 0.5 A or 1 A under a voltage of at least 230 Vac.

Switch 30 is a mechanical switch, normally closed, which switches between a stable state and an unstable state. It comprises two fixed electrical pads 34 and 36 and a movable electrical contact 38. Pad 34 is connected by an electric wire 40 to terminal 20 of actuator 10. Pad 36 is connected by an electric wire 42 to a terminal 44 of the electronic card 14.

Contact 38 can be moved, by key 32, between a closed state and an open state. In the closed state, shown in the , the contact 38 electrically connects the pads 34 and 36 together. In the open state, contact 38 electrically isolates pads 34 and 36 from each other.

Since switch 30 is a normally closed switch, in the absence of external stress on key 32, contact 38 is in its closed state. The switch 30 is housed inside a casing 50 of the button 12. Here, the switch 30 therefore comprises only the two fixed pads 34 and 36. It does not include any additional pad that can be connected to the electronic card 14.

Key 32 moves, relative to housing 50, between a released position and a depressed position. In the depressed position, the key 32 is located more towards the inside of the housing 50 than in its released position. Contact 38 is in its open state only when the key is moved to its depressed position.

The button 12 also includes a proximity detector 52, housed inside the housing 50. This detector 52 makes it possible to detect the presence of a user's hand at a distance of less than 20 cm or 10 cm from the key 32 In response to the detection of a hand in this distance range, the detector 52 generates a detection signal which is transmitted to the electronic card 14. For this purpose, the detector 52 is connected, via a electric wire 54, to a terminal 56 of the electronic card 14. For example, here, the detector 52 is an infrared detector.

The electronic card 14 is located inside a casing 60 separate from the casing 50. This casing 60 can therefore be assembled and dismantled independently of the casing 50.

The electronic card 14 comprises in particular:
- a timed relay 62,
- a circuit 64 for controlling the relay 62, and
- a circuit 66 for detecting the state of switch 30.

The relay 62 is capable of switching between an idle state, represented in FIG. 1, and an active state. In the idle state, the relay 62 authorizes the tilting of the actuator 10 into its unlocked state in response to pressing the key 32. This idle state is a stable state, that is to say a state which is retained, even in the absence of power supply to the electronic card 16. Here, the idle state corresponds to a closed state of the relay 62. In this idle state, the relay 62 electrically connects the terminal 44 to a terminal 70 of the electronic card 14. This terminal 70 is itself connected by an electric wire 72 to the terminal 162 of the power source 16. Thus, when the relay 62 is in its rest state, the movement of the button 32 towards its depressed position makes it possible to cut off the power supply to the actuator 10 and therefore to make it switch to its unlocked state.

In the active state, relay 62 maintains actuator 10 in its unlocked state. Here, the active state corresponds to an open state of relay 62. In this open state, relay 62 cuts the power supply to actuator 10, and this regardless of the current state of switch 30. active state is an unstable state, that is to say that in the event of a power cut to the electronic card 16, the relay 62 automatically returns to its rest state and does not remain in this active state.

Circuit 64 controls the switching of relay 62 from its quiescent state to its active state in response to a depression signal and in response to a detection signal. More precisely, in response to the reception of one of these two signals, the circuit 64 commands the switching of the relay 62 towards its active state, then maintains the relay 62 in its active state for a predetermined duration T, then commands the automatic return and systematic relay 62 to its resting state. Thus, during the time T, the actuator 10 is maintained in its unlocked state, even if the user releases the key 32. The time T is set to allow enough time for the user to open the door. 4 from the moment he pressed the key 32. For example, the duration T is greater than 3 seconds or 5 seconds or 10 seconds. The duration T is also generally less than 1 minute.

To receive the sense signal, circuit 64 is connected to terminal 56. To receive the depression signal, circuit 64 is connected to sense circuit 66.

Here, circuit 64 includes a programmable microprocessor 76 and memory 78 containing the instructions executed by microprocessor 76 to control relay 62 in response to sense and press signals.

Detection circuit 66 is capable of detecting the state of switch 30 without it being necessary for button 12 to include pads other than pads 34 and 32. More specifically, circuit 66 is capable of:
- comparing the voltage between pads 34 and 36 with a predetermined threshold S ₁ , and
- To generate and transmit the depression signal to the circuit 64 as soon as this threshold S ₁ is crossed.

The voltage between pads 34 and 36 is representative of the state of switch 30. Indeed, when switch 30 is in its closed state, this voltage is zero or practically zero. Conversely, when the switch 30 is in its open state, this voltage is high and, generally, equal to or close to the supply voltage delivered by the source 16 of supply.

To achieve this, circuit 66 is connected between terminal 44 and a terminal 80 of electronic card 14. Terminal 80 is connected by an electric wire 82 to pad 34 of switch 30, without passing through the pad 36. For this, here, terminal 80 is directly connected to wire 40, for example, at terminal 20 or pad 34.

By way of illustration, the circuit 66 is made using a voltage/current adapter 67 and an optocoupler. The adapter 67 is a circuit designed to adapt the voltage and the current to the characteristics of the optocoupler so that the latter is not damaged by excessive voltages and/or currents.

The optocoupler comprises a light-emitting diode 86 and, for example, a phototransistor 88. Diode 86 begins to generate infrared light only when the voltage between terminals 44 and 80 exceeds threshold S ₁ . This then causes phototransistor 88 to turn on, which then generates the depression signal.

There represents the casing 50 of the button 12. This casing 50 is typically made of metal and in one piece. Here, it has a cylindrical body 100 and a front plate 102. The front plate 102 has a hole 104 to receive the key 32 to slide. The plate 102 has a front face whose surface is greater than 3 cm2 or 5 cm2 and on which various information is written.

There represents, in exploded view, various elements constituting the button 12. These elements are received inside the cylindrical body 100. The button 12 therefore comprises in particular:
- a ring 106 for retaining the key 32, inside the cylindrical body 100,
- a printed circuit 108, on which are fixed the pads 34 and 36 of the switch 30, and
- a cap 110 to close the rear part of the cylindrical body 100.

Here, the detector 52 is housed inside the key 32 and its sensitive face is located under the support face of the key 32. The detector 52 therefore moves at the same time as the key 32. It is connected to the printed circuit 108 by a flexible layer 112 of conductive wires.

Typically, the printed circuit 108 is electrically connected to electrical connection terminals made on a rear face of the cap 110.

There represents in detail the rear face of the printed circuit 108. The pads 34 and 36 are fixed, without any degree of freedom, on this rear face. The electrical contact 38 is for its part fixed to the key 32. Thus, when the key 32 is moved from its released position, represented on the , towards its depressed position, this moves electrical contact 38 away from pads 34 and 36. This therefore causes switch 30 to switch from its closed state to its open state.

Figures 5 and 6 show the button 12 and the housing 60 mounted and fixed on a receptacle 120. In these figures, the receptacle 120 is shown in transparency. The front plate 102 is pressed against a front face of the receptacle 120. The box 60, which includes the electronic card 14, is fixed to the rear face of the receptacle 120, so as not to be accessible from the outside.

The operation of system 2 is as follows. In normal operating mode, the unlocking of door 4 can be triggered in two different ways.

A first way consists in simply approaching the hand to key 32, but without touching this key. The detector 52 then detects the presence of the hand close to the key 32. It then generates a detection signal which is transmitted to the control circuit 64. Circuit 64 processes the detection signal, then controls the switching of relay 62 from its rest state to its active state. This switching cuts the power supply to actuator 10. Actuator 10 is then in its unlocked state and door 4 can be opened. The actuator 10 remains in this unlocked state as long as the relay 62 is maintained in its active state, that is to say for the duration T. Then, the relay 62 returns to its rest state, which automatically brings the actuator 10 in its locked state at the end of this duration T.

A second way consists in pressing the key 32 with your finger. This movement causes the switch 30 to switch to its open state. The power supply to actuator 10 is therefore interrupted and door 4 is unlocked. Moreover, in parallel, this switching of the switch 30 from its closed state to its open state is detected by the detection circuit 66. In response, circuit 66 generates and transmits the depression signal to driver circuit 64. In response to this depression signal, the circuit 64 controls the movement of the relay 62 from its rest state to its active state, then maintains the relay 62 in its active state for the duration T, then finally brings the relay 62 back into its state of rest. Under these conditions, the actuator 10 is maintained in its unlocked state for the entire duration T, even if the user has released the button 32 in the meantime.

In degraded operating mode, only button 32 unlocks the door. In this degraded mode of operation, pressing key 32 causes switch 30 to open. its depressed position. If button 12 is placed near door 4, this allows the user to open door 4.

The degraded operating mode makes it possible to open the door 4 even if the detector 52 or the electronic card 14 is faulty. For example, this makes it possible to open door 4 even if control circuit 64 no longer works and relay 62 is blocked in its rest state. As mentioned earlier, the degraded operating mode is important to ensure that an electronic failure cannot lead to the user being trapped inside the building.

There represents a system 140 for electrical unlocking of door 4, which can be used instead of system 2. System 140 is identical to system 2, except that:
- the actuator 10 is replaced by an actuator 150,
- the button 12 is replaced by a button 152, and
- the electronic circuit 14 is replaced by an electronic circuit 156.

Actuator 150 is in its locked state when not powered and in its unlocked state when powered by power source 16. Thus, actuator 150 operates in the opposite direction to actuator 10. For this, for example, the electromagnet 26 is replaced by an electromagnet 158. The electromagnet 158 comprises a permanent magnet which permanently generates a magnetic field which attracts the ferromagnetic plate 24 and locks the door 4 in its closed position in the no power supply to actuator 150. When actuator 150 is powered, electromagnet 158 generates a magnetic field which cancels out that generated by the permanent magnet. Door 4 is unlocked and can be freely moved to its open position.

Button 152 is identical to button 12, except that switch 30 is replaced by a power switch 160. Switch 160 is a normally open switch, not a normally closed switch. Here, it comprises the same pads 34 and 36 and the same movable electrical contact 38. In its stable state, unlike switch 30, switch 160 is in an open state in which electrical contact 38 electrically isolates pads 34 and 36 from each other. Pad 36 is directly connected to terminal 162 of power source 16 by an electric wire 164. Thus, in its stable state, terminal 20 of actuator 150 is disconnected from terminal 162. Conversely, when switch 160 switches to its unstable state, it connects terminal 20 to terminal 162, which causes actuator 150 to switch to its unlocked state.

The electronic card 156 is identical to the electronic card 14, except that the relay 62 is replaced by a timed relay 172 and that the control circuit 64 is replaced by a control circuit 174.

Relay 172 is, for example, identical to relay 62, except that its resting state corresponds to an open state and the active state corresponds to a closed state. It is connected between terminals 70 and 80 of electronic card 156. Thus, in its rest position, it does not connect terminal 20 of actuator 150 to terminal 162. On the other hand, in its active state, it connects terminal 20 to terminal 162, and this independently of the state of switch 160.

The circuit 174 is for example structurally identical to the control circuit 64, except that the instructions recorded in the memory 78 are replaced by new instructions. When the new instructions are executed by the microprocessor 76, in response to the depression signal and in response to the detection signal, the circuit 174 controls the switching of the relay 172 from its rest state to its active state, then maintains the relay 172 in its active state for the duration T, then systematically returns the relay 172 to its idle state.

It will be noted that in this embodiment, the depression signal corresponds to an opening of the phototransistor 88, in response to the fact that the voltage between the pads 34 and 36 falls below the threshold S ₁ .

The operation of system 140 is deduced from the explanations given with reference to system 2, as well as from the structure of system 140 which has just been described.

In particular, as for system 2, in the event of failure of the detector 52 or of the control circuit 174, the user can always unlock the door 4, and this despite such electronic failures.

Chapter II: Variants

The detection circuit can be placed elsewhere than on the electronic board. For example, as a variant, the detection circuit is made on the printed circuit 108 of the push button. In another embodiment, this detection circuit is placed on an electronic card independent of the electronic card 14 and of the printed circuit 108.

Other embodiments of the detection circuit are possible. For example, the detection circuit comprises, in place of the optocoupler, a transistor which switches to its closed position when the voltage between its gate and its source falls below the predetermined threshold S ₁ . As a variant, instead of comparing the voltage between pads 34 and 36 with the threshold S ₁ , the detection circuit compares the intensity of the current which flows between pads 34 and 36 with a predetermined threshold. Indeed, the intensity of the current which circulates between the pads 34 and 36 is also a physical quantity representative of the state of the power switch 30.

In a simplified embodiment, the push button has no proximity detector. Conversely, in other embodiments, the push button incorporates additional electronic components such as LEDs.

Switch 30 may also include additional fixed pads which are not electrically connected to the detection circuit by wires. For example, these additional pads are used to perform a function other than that of controlling relay 62 or 172 depending on the position of key 32.

Other embodiments of the actuator are possible. For example, the actuator is not an electromagnetic lock, but an electric strike. The actuator can also be powered by an alternating voltage.

The positions of plate 24 and electromagnet 26 can be reversed. In this case, the electromagnet 26 is fixed on the leaf 6. This is, for example, interesting if the button 12 and the electronic circuit 14 are also fixed on this leaf 6.

The electronic card can integrate additional circuits, such as:
- a circuit which triggers the activation of a buzzer as long as the power supply to the actuator 10 is cut off, and/or
- An interface circuit for connecting the electronic card 14 to a building access management unit.

Chapter III: Advantages of the Embodiments Described

The fact of using a detection circuit connected between the fixed pads 34, 36 of the push button makes it possible to avoid having to use additional fixed pads in the push button to drive the timed relay. Therefore, it is possible to limit the number of fixed pads in the push button and therefore to simplify and reduce the internal bulk of the push button. This reduction in the size of the electrical components of the push button can then be used to accommodate the detector 52, while maintaining the size of the housing 50, for example, unchanged.

The fact of using the detection circuit also makes it possible to limit the number of wires which connect the push button to the external electronic card.

The fact of realizing the circuit of piloting of the delayed relay and the circuit of detection on the same electronic card simplifies the manufacture and the installation of the system.

The fact that the actuator 10 is in its unlocked state when its power supply is cut makes it possible to guarantee that in the event of a failure of the power source 16, the door 4 is unlocked and therefore that no user remains trapped there. interior of the building.

The fact that the actuator 150 is in its locked state when it is not powered saves energy.

Claims (8)

Electric unlocking system for a door comprising:
- an electric actuator (10; 150) capable of switching between:
- a locked state in which it keeps the door locked, and
- an unlocked state in which it keeps the door unlocked,
this actuator comprising first and second supply terminals (20, 22) intended to be connected to a supply source (16) to receive the supply necessary for its operation, and this actuator switching between its locked and unlocked states by connecting and, alternately, by disconnecting its first supply terminal to this supply source,
- a push button (12; 152) comprising:
- a pulse switch (30; 160) capable of switching between:
- a stable state in which it maintains the actuator in its locked state, and
- an unstable state in which it maintains the actuator in its unlocked state,
this switch comprising for this:
- first and second fixed electrical pads (34, 36), the first pad (34) being connected to the first power supply terminal (20) of the electrical actuator via a first wire (40) and the second pad (36) being connected to the power source (16) via a second wire (42; 164),
- an electrical contact (38) reversibly movable between:
- a closed state in which it electrically connects the first and second pads together, and
- an open state in which the first and second pads are electrically isolated from each other,
- a key (32) movable by a user to move the switch from its stable state to its unstable state,
- an electronic card (14; 156) external to the push button, this electronic card comprising:
- a timed relay (62; 172) switchable between:
- a state of rest in which it authorizes the switching of the actuator to its unlocked state in response to the displacement of the key of the push button, and
- an active state in which it maintains the electric actuator in its unlocked state even if the switch is in its stable state,
- a circuit (64; 174) for controlling the timed relay able, in response to the reception of a depression signal, to switch the timed relay from its resting state to its active state and then to maintain the timed relay in its active state for a predetermined duration before automatically returning to its idle state,
characterized in that the system comprises a circuit (66) for detecting the state of the switch connected between the first and second fixed pads (34, 36), this detection circuit being able:
- comparing the voltage or the intensity of the current between the first and second fixed pads of the switch, with a predetermined threshold, and
- In response to the crossing of this predetermined threshold, to generate and transmit the depression signal to the control circuit. System according to claim 1, in which the detection circuit (66) is integrated into the external electronic card. System according to any one of the preceding claims, in which only the first and second fixed pads (34, 36) of the switch are electrically connected to the electronic card. A system according to any preceding claim, wherein
the resting state of the timed relay (62; 172) is a stable state, that is to say that in the event of a power cut to the electronic card, the timed relay automatically returns to this resting state . A system according to any preceding claim, wherein:
- the push button comprises a proximity detector (52) capable of detecting, without contact, the presence of a hand in front of the button of the push button, and of transmitting a detection signal to the control circuit,
- the control circuit (64; 174) is also able, in response to the reception of the detection signal, to switch the timed relay from its resting state to its active state and then to maintain the timed relay in its active state for a predetermined period of time before automatically returning to its idle state. A system according to any preceding claim, wherein:
- the locked state of the electric actuator (10) is a state in which the electric actuator is powered and the unlocked state of the electric actuator is a state in which the electric actuator is not powered,
- the switch (30) of the push button (12) is a normally closed switch such that its stable state corresponds to a state where the electrical contact is in its closed state and its unstable state corresponds to a state where the electrical contact is in its open state,
- The idle state of the timed relay (62) corresponds to a closed state of this timed relay and the active state of the timed relay corresponds to an open state of this timed relay. System according to any one of claims 1 to 5, in which:
- the locked state of the electric actuator (150) is a state in which the electric actuator is not powered and the unlocked state of the electric actuator is a state in which the electric actuator is powered,
- the switch (160) of the push button (152) is a normally open switch such that its stable state corresponds to a state where the electrical contact is in its open state and its unstable state corresponds to a state where the electrical contact is in its closed state,
- the idle state of the time delay relay (172) corresponds to an open state of this time delay relay and the active state of the time delay relay corresponds to a closed state of this time delay relay. External electronic card (14; 156) for producing a system in accordance with any one of the preceding claims, in which this electronic card comprises:
- a timed relay (62; 172) switchable between:
- a state of rest in which it authorizes the switching of the actuator to its unlocked state in response to the displacement of the key of the push button, and
- an active state in which it maintains the electric actuator in its unlocked state even if the switch is in its stable state,
- a circuit (64; 174) for controlling the timed relay able, in response to the reception of a depression signal, to switch the timed relay from its resting state to its active state and then to maintain the timed relay in its active state for a predetermined duration before automatically returning to its idle state,
characterized in that the electronic card comprises a circuit (66) for detecting the state of the switch connected between the first and second fixed pads, this detection circuit being able:
- comparing the voltage or the intensity of the current between the first and second fixed pads of the switch, with a predetermined threshold, and
- In response to the crossing of this predetermined threshold, to generate and transmit the depression signal to the control circuit.